An Anti-SARS-CoV-2 Formula Consisting Volatile Oil from TCM Through Inhibiting Multiple Targets In vitro
Received: 17-Jun-2024 / Manuscript No. JIDT-24-139241 / Editor assigned: 19-Jun-2024 / PreQC No. JIDT-24-139241 (PQ) / Reviewed: 03-Jul-2024 / QC No. JIDT-24-139241 / Revised: 10-Jul-2024 / Manuscript No. JIDT-24-139241 (R) / Published Date: 17-Jul-2024 DOI: 10.4172/2332-0877.1000600
Abstract
At present, coronavirus severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) and its variant virus are prevalent all over the world, taking a major toll on human lives worldwide. Oral mucosa and saliva are the high-risk routes of transmission. Inactivation of the virus in the mouth is one of the important strategies to reduce the source infectivity of the virus. However, the current preparations for inactivating oral virus are mainly aimed at Angiotensin Converting Enzyme2 (ACE2) protein, and its effect needs to be improved. In this study, through literature mining, multi-target screening and other methods, we screened and optimized the volatile oil formula (Artemisiae argyi folium, Chrysanthemum morifolium, Trollii chinensis flos, Lonicerae japonica flos) from the volatile oil of Traditional Chinese Medicine (TCM) to inhibit the invasion and replication of SARS-CoV-2. A test using pseudotype virus with S glycoprotein confirmed that this formula could effectively bind to the S glycoprotein to prevent SARS-CoV-2 host cell entry. Molecular docking experiments showed that the multiple molecules in the formula might weakly bind to these targets including ACE2, cathepsin L, furin, Mpro or 3cl. In all, the volatile oil formula designed here offers a general affordable strategy to protect patients from SARS-CoV-2 infections through debulking or minimizing transmission to others.
Keywords: SARS-CoV-2; Formula; Traditional Chinese Medicine (TCM); Multiple targets; Volatile oil
Introduction
Globally, the severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) outbreak has caused millions of infections and tens of thousands of deaths. The spread of SARS-CoV-2 occurs both through droplets and aerosols, and is strongly linked to indoor exposures of infected individuals, whether they are symptomatic or not [1]. In saliva, high levels of SARS-CoV-2 virus are often detected [2]. Both asymptomatic and symptomatic COVID-19 patients have high SARS-CoV-2 viral loads in saliva [3,4]. In fact, COVID-19 symptoms include the loss of taste and smell, and viral replication occurs in salivary glands and oral mucous membranes [5]. Therefore, Virus inactivation within the oral cavity may be an effective strategy to reduce the spread of SARS-CoV-2 through the oral mucous membranes and saliva.
A better understanding of how SARS-CoV-2 take over the host during infection is essential for constructing therapeutic strategies. In fact, SARS-CoV-2 replication relies on many proteins or enzymes from the virus itself and the host cell [6]. In principle, these proteins and enzymes represent potential therapeutic targets. Coronaviruses start their life cycles when their S proteins bind to Angiotensin-Converting Enzyme 2 (ACE2) on host cells' surface membranes [7]. According to a previous description, the pre-fusion conformation is initiated by the proteolytic cleavage of the S1/S2 site, catalyzed by serine-proteases like furin or cathepsin L in correspondence of the (R/K)-(2X)n-(R/K) motif of S [8,9]. As a result of furin cleavage of the S1 (SPRRARY S) site of SARS-CoV-2, spike glycoprotein activation takes place, allowing the virus to enter the host. It is a polybasic cleavage site found in SARS-CoV-2, also known as a multibasic cleavage site. In COVID-19 patients, Cathepsin-L is thought to play a critical role since its levels are elevated after SARS-CoV-2 infection and positively correlate with disease severity [10]. Functionally, SARS-CoV-2 infection is enhanced by cathepsin-L by cleaving furin-primed SARS-CoV-2 S protein into smaller fragments and promoting cell-cell fusion [10,11]. Subsequently, the coronavirus main proteinase (3CLpro) of the virus cleaves viral replicase polyprotein into effector proteins [12]. Considering their undeniable role in the entry and replication of viruses, it may be possible to inhibit or modulate these four proteins (Angiotensin-Converting Enzyme (ACE2), furin, cathepsin L and 3CLpro) to develop effective antiviral therapies.
Currently, the oral preparation used to inactive SARS-CoV-2 are mainly aiming to act on the ACE2 target, which plays a major role in the invasion of host. Daniell et al., developed a chewing gum with converting enzyme 2 proteins to decrease oral virus transmission and infection through debulking SARS-CoV-2 in saliva [13]. Another study demonstrated newly synthesized polypeptides inhibits eliminating the invading virus by competing with SARS-CoV-2 for the ACE2 receptors [14]. However, these Oral preparation have been exclusively focused on one single protein target. Based on the fact that viruses go through various stages of their life cycle, an effective strategy involves targeting multiple viral proteins it enables the potential preparation to disrupt the viral infection and replication process in different stages as a result, the effect of killing viruses is maximized [15].
Recent studies showed that Traditional Chinese Medicine (TCM) could acts on multiple targets and multiple pathological processes, which provided us a valuable resource [16]. Traditional Chinese medicine volatile oil rich in ketones, terpenes, aldehydes, alcohols and other active substances is the product of plant metabolism extracted from plants by specific methods [17]. It is widely used in development of drugs, antibacterial agents, antiviral agents and other products due to its activities of enhancing immunity, bacteriostasis and antiviral [18,19]. Moreover, it has aromatic components, and the raw materials are simple and easy to obtain. Compared with traditional chemical drug products, volatile oil can possess more efficient antibacterial activity and are not easy to produce resistance limitation, with lower cytotoxicity [19,20]. Thus, it is feasible to develop safe and environment-friendly anti-SARS-COVID-2 oral preparation from the volatile oil of traditional Chinese medicine.
In this research, we screened from the volatile oils of Traditional Chinese Medicine based on literature review and multiple target screening and obtain an effective formula. Then, the effect of the formula was investigated by in vitro assay. Finally, we use molecular docking to preliminarily explore the mechanism of this compound against SARS-CoV-2.
Materials and Methods
Reagents and cell culture
HEK293T–overexpressing ACE2 cell were purchased from GENEWIZ (Jiangsu, China) and grown in Dulbecco's Modified Eagle Medium (DMEM) (gibco, thermo fisher scientific, waltham, MA, USA) containing 10% fetal bovine serum (Gibco; hereinafter referred to as complete medium), 100 U/mL penicillin, 100 μg/mL streptomycin and 1 μg/mL puromycin and incubated at 37°C in an atmosphere containing 5% CO2/95% air.
Literature mining
All Raw data is uploaded as supplementary file. All data generated or analyzed during this study are included in this published article and its supplementary information files.
“Traditional Chinese medicine”, “volatile oil” and “antiviral” were used as key words for a comprehensive search of both english and chinese-language literature in PubMed, and CNKI (Chinese National Knowledge Infrastructure) databases from May 2000 to May 2022. For overlapping or republished studies, only the most recent published papers were included. There are 214 references and 62 kinds of single Traditional Chinese Medicine volatile oils are retrieved. Finally, 9 kinds of Traditional Chinese Medicine volatile oils was obtained according to the in vitro antiviral mechanism.
Extraction of volatile oil by hydrodistillation
5 kgs of 9 kinds TCM were purchased from anguo kanghua Traditional Chinese Medicine sales Co. Ltd. (Hebei, China).
Each of above TCM was subjected to hydrodistillation for 2 h, to extract volatile oil, and the volatile oil was then kept in a glass bottle after cooling down to the room temperature. The residual water was then removed, using anhydrous sodium sulfate. The yield of essential oil was calculated by using the following formula:
Where, a is a volume of the volatile oil, and b is the weight of fresh plant materials used in the hydrodistillation. The essential oil was stored at 4°C, in a light-protected container, until further use.
Cathepsin L activity assays
The cathepsin L activity screening assay kit (Biovision, California, USA) was used to determine the inhibitory effect of selected volatile oils on the activity of isolated cathepsin L enzyme according to the manufacturer’s protocol. Selected volatile oils at 0.5 mg/mL concentrations were added to cathepsin L (0.2 mU/μl) and the reaction mix was incubated for 15 min at RT. Positive control consisted of cathepsin L alone, whereas negative control consisted of cathepsin L and inhibitor (10 μM) of cathepsin L. Cathepsin L substrate was added to each well. The fluorescence was measured at Ex/Em=400/505 nm wavelength using a spectrofluorometer (thermofisher, Massachusetts, USA) in a kinetic mode for 30 min at 37°C. Control was 0.5% ethanol. Results are expressed as a percentage of volatile oil-free control (mean ± SD, n=6).
Angiotensin Converting Enzyme2 (ACE2) activity assays
To determine the inhibitory effect of selected volatile oils on the activity of recombinant hACE2 protein, an ACE2 activity screening assay kit (Beyotime, Shanghai, China) was used according to the manufacturer’s protocol. Briefly, the volatile oils at 0.5 mg/mL concentrations were added and the reaction mix was incubated for 45 min at RT. The positive control was a sample containing ACE2 enzyme and ACE2 enzyme inhibitor MLN-4760 (10 nm). The fluorescence was measured at Ex/Em=325/393 nm wavelength using a spectrofluorometer (thermofisher, Massachusetts, USA). 100% enzyme activity control was 0.5% ethanol. Results are expressed as a percentage of volatile oil-free control (mean ± SD, n=6).
Furin activity assays
To examine the effect of various selected volatile oils on furin activity, a furin Activity Screening Assay Kit (Biovision, California, USA) was used according to the manufacturer’s protocol. Briefly, the volatile oils at 0.5 mg/mL concentrations were added. furin substrate was added to each well. The positive control was a sample containing furin enzyme and furin inhibitor (10 nm). The fluorescence was measured at Ex/Em=360/460 nm wavelength using a spectrofluorometer (thermofisher,bMassachusetts, USA) in a kinetic mode for 1 h at 37°C. Results are expressed as a percentage of volatile oil-free control (mean ± SD, n=6).
Mpro or 3cl activity assays
To determine the inhibitory effect of selected volatile oils on the activity of Mpro or 3cl protein, an Mpro or 3cl activity screening assay kit (Beyotime, Shanghai, China) was used according to the manufacturer’s protocol. Briefly, the volatile oils at 0.5 mg/mL concentrations were added and the reaction mix was incubated for 45 min at Respiratory Therapist (RT). The positive control was a sample containing Mpro or 3cl enzyme and Mpro or 3cl enzyme inhibitor Ebselen (2 μm). The fluorescence was measured at Ex/Em=325/393 nm wavelength using a spectrofluorometer (thermofisher, Massachusetts, USA). 100% enzyme activity control was 0.5% ethanol. Results are expressed as a percentage of volatile oil-free control (mean ± SD, n=6).
Viability assay
In order to assess cell viability, we used the CCK-8 assay. Briefly, HEK-293T/ACE2 cells were seeded into a 96-well plate at a cell density of 6,000 per well, and allowed to adhere for 24 h, followed by treatment with different concentrations of selected volatile oils for up to 48 h. Afterwards, complete growth medium was replaced with a fresh one substituted with 10 μl CCK-8, followed by 3 hours at 37°C incubation. The absorbance was measured at 450 nm using a spectrophotometer (Molecular Devices, San Jose, CA). Results are expressed as a percentage of volatile oils-free control (mean ± SD, n=6).
Pseudovirus preparation and neutralization assay
For pseudovirus neutralization assay, 100 Tissue Culture Infectious Dose (TCID50) per well pseudovirus in medium without FBS was incubated with volatile oils combination for 30 min at room temperature. Then the mixtures (100 μL) were used to infect HEK- 293T/ACE2 cells rinsed with PBS. After 5 h, 100 μL medium with 5% FBS was added. After incubation for another 48 h, After 48 h, cells were lysed using Firefly Luciferase Assay Kit (Genescript, catalog no. L00877C), and relative light units were measured using a 96 Thermo Microplate luminometer. Percent neutralization was calculated using GraphPad Prism 8.
Molecular docking
Ligand preparation: For molecular docking studies, The structures of the all ligands were retrieved from European Molecular Biology Laboratory (EMBL)- European Bioinformatics Institute (EBI) (www. ebi.ac.uk/chebi/ advancedSearchFT.do), in a three-dimensional Structure File (SDF) format, and furthermore, the structure was refined using the ligprep module in schrodinger’s maestro (v 12.8). The OPLS4 force field was applied, and 32 different states of stereoisomerism were derived (Schrödinge release 2021-2: ligprep, schrödinge, LLC, New York, NY, 2021).
Protein preparation: we need to evaluate the furin (5JXH), Mpro (6W63), cathepsin L (3OF9) and anti ACE2 (1R42) activity against different ingredients in the each volatile oils computationally, respectively. The three-dimensional structure of proteins was retrieved from the database of Protein Data Bank (PDB). The X-ray crystallographic structures were imported into Maestro using the protein preparation wizard, and this module helps to solve the missing hydrogen bonds, create the disulfide bonds, and optimize (Schrödinge Release 2021-2: Protein Preparation Wizard; Epik, Schrödinge, LLC, New York, NY, 2021; Impact, Schrödinge, LLC, New York, NY; Prime, Schrödinge, LLC, New York, NY, 2021).
The molecular docking was performed using the Glide package (ligand docking) in the Schrodinger suite. The standard precision docking method was applied and performed postdocking minimization and analyzed the results in pose viewer Schrödinge Release 2021-2: Glide, Schrödinge, LLC, New York, NY, 2021
Statistical analysis
All data in experiments were analyzed using Prism 8.0 software and are presented as mean ± SEM. Statistical significance was assessed by one-way Analysis of Variance (ANOVA). P value
Results and Discussion
Validation of TCMs volatile oil for antiviral activity
Antiviral research has been an active field in recent decades. To date, at present, many Traditional Chinese Medicines have been reported to have antiviral effects. In the long history of chinese medicine, some TCMs volatile oil have been reported to have antiviral benefits. Thus, TCMs volatile oil are great candidates for screening and verifying their antiviral properties. To choose TCM volatile oil candidates for validation, we searched the National Pubmed as well as China National Knowledge Infrastructure (CNKI) for antiviral TCMs volatile oil. The mechanism of Traditional Chinese Medicine can be divided into direct inhibition and indirect inhibition. The direct inhibition is mainly to block a certain link in the process of virus reproduction to defeat pathogen propagation; Indirect inhibition is to stimulate and mobilize the immune defense system of the body to play an antiviral role [21]. Since we only consider the direct antiviral effect, that is, to inhibit the virus invasion and replication in the host, we finally get 9 Chinese herbal volatile oils through screening, as shown in Table 1.
TCM | Scientific name | Refractive index | pH | Density |
---|---|---|---|---|
Shi xiang ru | Moslae Herba | 1.4718 | 4.4 | 0.9012 |
Ma ye qian li guang | Senecionis scandentis hebra | 1.4716 | 4.4 | 0.9555 |
Yu xing cao | Houttuyniae herba | 1.3408 | 4.4 | 0.8756 |
Hong feng | Acer palmatum 'atropurpureum', | 1.339 | 4.4 | 0.9227 |
Ai ye | Artemisiae argyi folium | 1.3334 | 4.4 | 0.9946 |
Jin lian hua | Lonicerae japonica flos | 1.3343 | 4.4 | 0.8768 |
Hang bai ju | White chrysanthemum indicum | 1.3338 | 4.1 | 0.96 |
Ye ju hua | Chrysanthemi indici flos | 1.3361 | 4.4 | 0.8346 |
Jin yin hua | Trollius chinensis bunge | 1.4679 | 4.5 | 0.872 |
Table 1: Physicochemical characteristics of 9 volatile oils
ID | Name | Glide ligand efficiency | Glide gscore | Glide energy |
---|---|---|---|---|
CHEBI:171934 | Isocyclocitral | -0.364 | -4.007 | -17.951 |
CHEBI:89773 | 1,2-Dihydro-1,1,6-trimethylnaphthalene | -0.277 | -3.596 | -17.596 |
CHEBI:167345 | Cedrene | -0.238 | -3.564 | -19.948 |
CHEBI:167347 | gamma-Selinene | -0.226 | -3.383 | -15.157 |
CHEBI:10357 | (-)-beta-Caryophyllene | -0.187 | -2.807 | -9.286 |
CHEBI:180521 | D6-Ambrettolide | -0.154 | -2.763 | -12.213 |
CHEBI:63190 | (+)-beta-Caryophyllene | -0.179 | -2.68 | -10.828 |
CHEBI:62224 | (-)-7-epi-alpha-Selinene | -0.175 | -2.629 | -15.377 |
CHEBI:62757 | alpha-Curcumene | -0.169 | -2.529 | -17.887 |
CHEBI:64361 | beta-Sesquiphellandrene | -0.164 | -2.465 | -15.725 |
CHEBI:84851 | Ehyl linolenate | -0.085 | -1.862 | -30.722 |
CHEBI:31572 | Ethyl linoleate | -0.071 | -1.552 | -25.76 |
CHEBI:34687 | Dibutyl phthalate | -0.034 | -0.681 | -27.935 |
CHEBI:32936 | Tetracosane | 0.001 | 0.013 | -26.007 |
CHEBI:46050 | Docosane | 0.002 | 0.037 | -22.23 |
CHEBI:17327 | Phytol | 0.029 | 0.611 | -25.452 |
CHEBI:39238 | (Z,E)-alpha-Farnesene | 0.049 | 0.742 | -17.625 |
CHEBI:17351 | Linoleic acid | 0.071 | 1.42 | -22.532 |
CHEBI:69080 | Methyl linoleate | 0.072 | 1.515 | -25.416 |
CHEBI:10418 | trans-beta-Farnesene | 0.111 | 1.669 | -18.428 |
CHEBI:30813 | Decanoic acid | 0.161 | 1.927 | -14.954 |
CHEBI:15756 | Hexadecanoic acid | 0.133 | 2.394 | -21.115 |
CHEBI:43619 | Icosane | 0.154 | 3.077 | -22.779 |
CHEBI:16148 | Heptadecane | 0.189 | 3.221 | -20.402 |
CHEBI:32927 | Nonadecane | 0.171 | 3.249 | -21.935 |
CHEBI:32926 | Octadecane | 0.189 | 3.405 | -20.733 |
CHEBI:132293 | 2-Methylicosane | 0.162 | 3.407 | -21.296 |
Table 2: Molecular docking results of the essential oil from hang bai ju (White chrysanthemum indicum) with ACE2
Four volatile oils inhibit the activity of different targets of SARS-COV-2, respectively
As the life cycle of SARS-CoV-2 is related to multiple protein targets, as shown in Figure 1 and 2, in order to better prevent SARS-CoV-2 from invading and replicating, we screened volatile oils that can inhibit these four targets, including ACE2, furin, cathepsin L and Mpro or 3cl. The angiotensin-converting enzyme II (ACE2) has been recognized as the host receptor of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2). There is a strong interaction between the receptor binding domain of the SARS-CoV-2 S-protein and ACE2, in this way, ACE2 may provide an effective drug target for preventing COVID-19 from invading host cells [22]. The screening results are shown in Figure 3A. The volatile oil of Hang bai ju (White Chrysanthemum indicum) is the best one to target ACE2.
Furin converts synthesized proteins into biologically active forms by cleaving a specific section [23]. It is a serine endoprotease that cleaves precursor protein processing sites in a calcium-dependent manner. Furin cleaves S1 (SPRRARY S) site of SARS-CoV-2, direct emergence in spike glycoprotein activation for viral entry into the host system [24]. The screening results are shown in Figure 3B. Among the volatile oils of Traditional Chinese Medicine targeting furin protease, the volatile oil of Ai ye (Artemisiae argyi folium) has the best inhibitory effect.
Figure 3: Target screening of volatile oil against SARS-CoV-2. Note: (A) Jin lian hua (Lonicerae japonica flos) inhibited the activity of Mpro/3cL at maximal levels; (B) Hang bai ju (White Chrysanthemum indicum) inhibited the activity of ACE2 at maximal levels; (C) Jin yin hua (Trollius chinensis bunge) inhibited the activity of cathepsin L at maximal levels; (D) Ai ye (Artemisiae argyi folium) inhibited the activity of furin at maximal levels. The data represent results combined from three independent experiments. *p<0.05, **p<0.01, ***p<0.001 compared to 100% enzyme activity control.
Cathepsin-L plays a critical role in COVID-19 patients, as evidenced by high circulating levels after SARS-CoV-2 infections, and a positive correlation with disease severity [25]. Functionally, It helps promote SARS-CoV-2 infection by fragmenting furin-primed SARS-CoV-2 S proteins and facilitating cell-to-cell fusion by cleaving them into smaller fragments [9,11]. Results as shown in Figure 3C, the inhibitory effect of honeysuckle volatile oil on cathepsin L was the best.
Mpro is highly conserved among different CoVs, and as far as we known, It has no human homolog, and shows a low mutation rate, making it ideal for the development of multi-viral drugs that can interfere with different varieties of SARS-CoV-2 and other coronaviruses’ vital cycles [26,27]. The screening results are shown in Figure 3D. Among the volatile oils of Traditional Chinese Medicine targeting the main protease, the volatile oil of Jin lian hua (Trollius chinensis) has the best inhibitory effect.
Neutralization assay with SARS-COV-2 spike-pseudotyped lentiviral particles
For maximum antiviral effect, we design a combination containing 0.25 mg/mL. The anticoronavirus activity of the formula was further explored by pseudovirus neutralization test. Pseudoviruses containing the viral spike protein and expressing the luciferase reporter gene were used to infect Human Embryonic Kidney Cells. (HEK293) expressing human ACE2. The formula at the indicated concentration was incubated at room temperature for 90 minutes with spike glycoprotein pseudotyped viruses expressing luciferase expressed by the SARSCoV- 2 virus. Then, virus-containing the formula was incubated with ACE2-expressing HEK293 cells for 72 h, and viral infectivity was measured via luciferase. The incubation of pseudotyped lentivirus with the four kind volatile oil and the formula significantly reduced luciferase activities, and at 1 mg/ml of the highest inhibition was observed (Figure 4), confirming the ability of this formula to block entry of lentivirus spike protein into HEK293 cells either by direct inhibiting ACE2 or cathepsin L or furin or Mpro or 3cl protein on HEK293 cells. In addition, the effects of the formula on the cell viability were also evaluated, and it demonstrated no cytotoxicity (Figure 5).
The volatile oil in this article were rationally designed to target multiple targets either on viral entry or replication. The volatile oil in this article is a multiple target targeting COVID-19, This concept is consistent with the idea of drug discovery targeting COVID-19 multi protein reported previously [15]. The definition of a drug target is important to the success of drug discovery [28]. An antiviral agent targeting multiple viral proteins is a novel concept. Similar to drug cocktail screening, drug combination screening involves selecting drug candidates that target and block different stages of the virus’ life cycle. Contrary to the majority of existing repurposed drug research, this work focuses on multiple targets at once. Thus, our approach has the potential to attack the virus from different angles if successful.
Exploring the antiviral mechanism of formula based on molecular docking
The antiviral mechanisms of four each volatile oil could preliminarily obtained through the literature. It is reported that the volatile oil of Ai ye (Artemisiae argyi folium) has inhibitory effect on herpes zoster virus [29], Respiratory Syncytial Virus (RSV), Influenza Virus (IFV) and Hepatitis B Virus (HBV) [30,31]. Artemisol and other components can inhibit bacteria and viruses [31]. Linalool, geraniol and a-terpineol from the volatile oil of Jin yin hua (Trollius chinensis bunge) hua have antiviral effects [32]. Hai et al., reported that volatile compounds are one of the main active ingredients of Hang bai ju (White Chrysanthemum indicum), which have a significant anti influenza virus (H3N2) effect [33,34]. Zhao et al., found that the ethanol extract of Jin lian hua (Trollius chinensis) has obvious inhibitory effect on virus replication in chicken embryos, and has direct killing effect on H1N1 virus PR8 strain [35].
We next asked what is the specific mechanism underlying anti–COVID19 efficacy of the formula. It is necessary to explicitly determine the main components of these volatile oils. According to reports in the literature, volatile oil of Hang bai ju (White Chrysanthemum indicum), Ai ye (Artemisiae argyi folium), Jin yin (Trollius chinensis bunge) hua and jin lian hua (Trollius chinensis) mainly contains components respectively, as shown in Tables 2-5. To investigate the interactions between component of volatile oil and different targets, molecular docking experiments were performed [36-39]. The component of the four kinds of essential oil were docked within the active site of four target using Extra Precision (XP) mode of Glide docking module of Maestro, respectively. Based on the docking scores, the compounds were ranked. PyMOL was used to visualize ligand-receptor interactions within the protein's active site. The results shown that isocyclocitral from Hang bai ju (White Chrysanthemum indicum), spathulenol from Ai ye (Artemisiae argyi folium), benzyl benzoate from Jin yin hua (Trollius chinensis bunge), and beta-ionone from Jin lian hua (Trollius chinensis) bind at the active site of ACE2, furin, cathepainL and Mpro or 3cl of SARS-CoV-2 with the dock score -4.007 kcal/mol, -4.995 kcal/mol, -6.146 kcal/mol and -4.927 kcal/mol, respectively (Tables 2-5 and Figure 6). Moreover, it also demonstrated that other components of each volatile oil could act on the corresponding target, even though the interaction between them is very weak.
ID | Name | Glide ligand efficiency | Glide gscore | Glide energy |
---|---|---|---|---|
CHEBI:132824 | spathulenol | -0.312 | -4.995 | -29.469 |
CHEBI:167328 | 2-p-Menthen-1-ol | -0.435 | -4.781 | -22.01 |
CHEBI:176780 | Dihydroactinidiolide | -0.365 | -4.739 | -21.911 |
CHEBI:50040 | Thujone | -0.429 | -4.715 | -18.481 |
CHEBI:4609 | Dimethyl phthalate | -0.322 | -4.514 | -27.789 |
CHEBI:17854 | Cyclohexanone | -0.636 | -4.454 | -18.001 |
CHEBI:22469 | alpha-Terpineol | -0.405 | -4.454 | -26.024 |
CHEBI:173721 | Davanone | -0.262 | -4.453 | -29.093 |
CHEBI:27961 | 1,8-cineole | -0.39 | -4.29 | -19.998 |
CHEBI:3573 | Chamazulene | -0.301 | -4.209 | -22.475 |
CHEBI:132905 | alpha-Cadinol | -0.256 | -4.094 | -23.184 |
CHEBI:28093 | borneol | -0.372 | -4.088 | -19.503 |
CHEBI:132899 | beta-Terpineol | -0.371 | -4.078 | -26.049 |
CHEBI:29069 | Phthalic acid | -0.336 | -6.432 | -30.927 |
CHEBI:36773 | Camphor | -0.366 | -4.03 | -18.778 |
CHEBI:156228 | Viridiflorol | -0.251 | -4.017 | -23.82 |
CHEBI:15397 | (S)-Camphor | -0.364 | -4.003 | -18.068 |
CHEBI:49045 | Germacrene D | -0.26 | -3.893 | -22.31 |
CHEBI:10577 | gamma-Terpinene | -0.368 | -3.684 | -18.022 |
CHEBI:61699 | (-)-alpha-Gurjunene | -0.246 | -3.683 | -25.021 |
CHEBI:63709 | Bicyclogermacrene | -0.24 | -3.595 | -24.5 |
CHEBI:50025 | beta-Pinene | -0.331 | -3.31 | -15.545 |
CHEBI:17327 | Phytol | -0.072 | -1.503 | -39.271 |
CHEBI:145715 | hex-3-en-1-ol | -0.158 | -1.108 | -17.563 |
CHEBI:185431 | Pentane-1,5-diol | -0.143 | -1.001 | -23.626 |
CHEBI:39242 | cis-beta-Farnesene | 0.05 | 0.743 | -25.779 |
CHEBI:17302 | Pentadecanal | 0.136 | 2.173 | -30.775 |
Table 3: Molecular docking results of the essential oil from Ai ye (artemisiae argyi folium) with furin
ID | Name | Glide ligand efficiency | Glide gscore | Glide energy |
---|---|---|---|---|
CHEBI:41237 | Benzyl benzoate | -0.384 | -6.146 | -32.778 |
CHEBI:28266 | Fluorene | -0.454 | -5.901 | -24.18 |
CHEBI:22469 | Alpha-terpineol | -0.535 | -5.89 | -25.072 |
CHEBI:28851 | Phenanthrene | -0.416 | -5.83 | -24.734 |
CHEBI:34247 | 2,6-di-tert-butyl-4-methylphenol | -0.342 | -5.472 | -23.883 |
CHEBI:32319 | Alpha-ionone | -0.35 | -4.906 | -23.664 |
CHEBI:84851 | Ethyl linolenate | -0.17 | -3.745 | -36.322 |
CHEBI:32936 | Tetracosane | -0.15 | -3.595 | -35.184 |
CHEBI:17447 | Geraniol | -0.325 | -3.575 | -23.114 |
CHEBI:32941 | Heptacosane | -0.114 | -3.082 | -39.933 |
CHEBI:32938 | Pentacosane | -0.106 | -2.659 | -34.403 |
CHEBI:17580 | Linalool | -0.236 | -2.598 | -21.637 |
CHEBI:149547 | (2E,4E)-deca-2,4-dienal | -0.233 | -2.568 | -24.047 |
CHEBI:46050 | Docosane | -0.1 | -2.211 | -35.118 |
CHEBI:34687 | Dibutyl phthalate | -0.098 | -1.956 | -39.578 |
CHEBI:67252 | Farnesyl acetone | -0.097 | -1.85 | -32.469 |
CHEBI:17351 | Linoleic acid | -0.092 | -1.846 | -38.83 |
CHEBI:177721 | methyl 9-oxononanoate | -0.073 | -0.946 | -29.415 |
CHEBI:17327 | Phytol | -0.033 | -0.683 | -32.077 |
CHEBI:42504 | Pentadecanoic acid | -0.039 | -0.664 | -33.772 |
CHEBI:15756 | Hexadecanoic acid | -0.024 | -0.442 | -36 |
CHEBI:28842 | Octadecanoic acid | -0.02 | -0.397 | -39.091 |
CHEBI:30805 | Dodecanoic acid | -0.028 | -0.396 | -29.905 |
CHEBI:30813 | Decanoic acid | -0.033 | -0.394 | -28.055 |
CHEBI:69187 | Methyl palmitate | -0.015 | -0.277 | -33.707 |
CHEBI:69080 | Methyl linoleate | -0.011 | -0.224 | -35.128 |
CHEBI:28875 | Tetradecanoic acid | 0 | -0.004 | -30.723 |
CHEBI:69188 | Methyl stearate | 0.006 | 0.136 | -36.556 |
CHEBI:84156 | Methyl palmitoleate | 0.016 | 0.312 | -33.112 |
CHEBI:84067 | Tetradecanal | 0.064 | 0.956 | -29.986 |
CHEBI:45296 | Hexadecane | 0.111 | 1.774 | -28.734 |
CHEBI:32927 | Nonadecane | 0.099 | 1.884 | -30.142 |
Table 4: Molecular docking results of the essential oil from Jin yin hua (Trollius chinensis bunge) with Cathepsin L
ID | Name | Glide ligand efficiency | Glide gscore | Glide energy |
---|---|---|---|---|
CHEBI:32325 | Beta-ionone | -0.352 | -4.927 | -27.773 |
CHEBI:67206 | Geranyl acetone | -0.325 | -4.554 | -27.44 |
CHEBI:42438 | 2-methoxy-4-vinylphenol | -0.402 | -4.422 | -23.155 |
CHEBI:67252 | Farnesyl acetone | -0.212 | -4.035 | -29.67 |
CHEBI:17351 | Linoleic acid | -0.192 | -3.843 | -32.227 |
CHEBI:16196 | Oleic acid | -0.187 | -3.741 | -35.214 |
CHEBI:46050 | Docosane | -0.166 | -3.663 | -31.617 |
CHEBI:17580 | Linalool | -0.329 | -3.614 | -22.597 |
CHEBI:28716 | Palmitoleic acid | -0.183 | -3.299 | -28.459 |
CHEBI:79053 | Diisobutyl phthalate | -0.164 | -3.287 | -31.689 |
CHEBI:69080 | Methyl linoleate | -0.156 | -3.276 | -32.755 |
CHEBI:17327 | Phytol | -0.147 | -3.087 | -26.609 |
CHEBI:28842 | Octadecanoic acid | -0.154 | -3.08 | -30.355 |
CHEBI:27432 | Alpha-linolenic acid | -0.144 | -2.893 | -31.987 |
CHEBI:29019 | Nonanoic acid | -0.248 | -2.735 | -21.532 |
CHEBI:133634 | Methyl linolenate | -0.13 | -2.725 | -35.695 |
CHEBI:42504 | Pentadecanoic acid | -0.144 | -2.444 | -27.718 |
CHEBI:16148 | Heptadecane | -0.144 | -2.441 | -29.375 |
CHEBI:28897 | Pentadecane | -0.157 | -2.355 | -26.189 |
CHEBI:87494 | Methyl laurate | -0.15 | -2.253 | -27.222 |
CHEBI:41808 | decane | -0.221 | -2.212 | -17.68 |
CHEBI:28875 | Tetradecanoic acid | -0.134 | -2.15 | -25.702 |
CHEBI:41253 | Tetradecane | -0.132 | -1.854 | -27.426 |
CHEBI:35998 | Tridecane | -0.123 | -1.599 | -26.364 |
Table 5: Molecular docking results of the essential oil from Jin lian hua (Lonicerae japonica flos) with Mpro/3cl
There are only five components of the volatile oil from Jin yinhua (Trollius chinensis bunge), whose docking score with absolute values were greater than 5, indicating that the binding ability of these volatile oil monomers to the target was weak. As is well known to all, herbs produce their efficacy through the synergistic effects of multi-ingredients, multi-targets, and multi-pathways [40,41]. Although the results show that the absolute value of the docking score between these volatile oil monomers and the target is relatively small, these volatile oils with multi-component synergizing on the common target can also achieve the effect of acting on the target.
Conclusion
In this work, we present a formula consisting volatile oil for anti-viral agents that interact with multiple target proteins of SARS-CoV-2. We first collected 9 antiviral volatile oils from the literature, Secondly, the volatile oil with the best inhibitory effect on the four targets was obtained by target screening. Then the formula consisting the four volatile oils has better effect of neutralizing pseudovirus compared with the effects of mono-agents. Overall, we found a volatile oil formula with potential inhibitory ability against 4 key proteins of SARS-CoV-2. The volatile oil can be used to develop oral or nasal preparations. A further study in animals is needed to determine if oral or nasal spray delivery is more effective as a preventative or curative measure. There are more than four targets related to the life cycle of novel coronavirus. In the future, we will further screen other targets to improve the efficacy of this formula.
Author Contribution
Conceptualization was primarily conducted by Huan Zhang and Bo Zhang. Methodology and resources were developed by Huan Zhang, Wuyan Guo, Jing Shen and Xiaorui Song. Validation and visualization were carried out by Huan Zhang and Wuyan Guo. Formal analysis involved contributions from Huan Zhang, Wuyan Guo, and Bo Zhang. The original draft was prepared by Huan Zhang, with subsequent writing review and editing conducted by Huan Zhang, Wuyan Guo and Bo Zhang. Bo Zhang provided supervision throughout the project. All authors have read and agreed to the published version of the manuscript.
Funding
This research was funded by China postdoctoral science foundation (2020T130093ZX) and the open research funding (ERC202307).
Data Availability
The data used to support the fndings of this study are available from the corresponding author upon request.
Declarations
Ethics approval
Not applicable.
Consent to participate
Not applicable.
Consent for publication
Not applicable.
Confict of interest
The authors declare no competing interests.
References
- Allen JG, Ibrahim AM (2021) Indoor air changes and potential implications for SARS-CoV-2 transmission. Jama 325:2112-2113.
[Crossref] [Google Scholar] [PubMed]
- Li Y, Ren B, Peng X, Hu T, Li J, et al. (2020) Saliva is a non-negligible factor in the spread of COVID‐19. Mol Oral Microbiol 35:141-145.
[Crossref] [Google Scholar] [PubMed]
- Chan JF, Yip CC, To KK, Tang TH, Wong SC, et al. (2020) Improved molecular diagnosis of COVID-19 by the novel, highly sensitive and specific COVID-19-rdrp/hel real-time reverse transcription-pcr assay validated in vitro and with clinical specimens. J Clin Microbiol 58:310-320.
[Crossref] [Google Scholar] [PubMed]
- Wölfel R, Corman VM, Guggemos W, Seilmaier M, Zange S, et al. (2020) Virological assessment of hospitalized patients with COVID-2019. Nature 581:465-469.
[Crossref] [Google Scholar] [PubMed]
- Huang N, Pérez P, Kato T, Mikami Y, Okuda K, et al. (2021) SARS-CoV-2 infection of the oral cavity and saliva. Nat Med 27:892-903.
[Crossref] [Google Scholar] [PubMed]
- Gil C, Ginex T, Maestro I, Nozal V, Barrado-Gil L, et al. (2020) COVID-19: Drug targets and potential treatments. J Med Chem 63:12359-12386.
[Crossref] [Google Scholar] [PubMed]
- Zhou P, Yang XL, Wang XG, Hu B, Zhang L, et al. (2020) A pneumonia outbreak associated with a new coronavirus of probable bat origin. Nature 579:270-273.
[Crossref] [Google Scholar] [PubMed]
- Coutard B, Valle C, De Lamballerie X, Canard B, Seidah NG, et al. (2020) The spike glycoprotein of the new coronavirus 2019-nCoV contains a furin-like cleavage site absent in CoV of the same clade. Antiviral res 176:104742.
[Crossref] [Google Scholar] [PubMed]
- Ou X, Liu Y, Lei X, Li P, Mi D, et al. (2020) Characterization of spike glycoprotein of SARS-CoV-2 on virus entry and its immune cross-reactivity with SARS-CoV. Nat Commun 11: 1620.
[Crossref] [Google Scholar] [PubMed]
- Zhao MM, Yang WL, Yang FY, Zhang L, Huang WJ (2021) Cathepsin L plays a key role in SARS-CoV-2 infection in humans and humanized mice and is a promising target for new drug development. Signal Transduct Target Ther 6:134-134.
[Crossref] [Google Scholar] [PubMed]
- Shang J, Wan Y, Luo C, Ye G, Geng Q, et al (2020). Cell entry mechanisms of SARS-CoV-2. Proc Natl Acad Sci 117:11727-11734.
[Crossref] [Google Scholar] [PubMed]
- Zhang L, Lin D, Sun X, Curth U, Drosten C, et al. (2020) Crystal structure of SARS-CoV-2 main protease provides a basis for design of improved alpha-ketoamide inhibitors. Science,368:409-412.
[Crossref] [Google Scholar] [PubMed]
- Daniell H, Nair SK, Esmaeili N, Wakade G, Shahid N, et al. (2021) Debulking SARS-CoV-2 in saliva using angiotensin converting enzyme 2 in chewing gum to decrease oral virus transmission and infection. Mol Ther 30:1966-78.
[Crossref] [Google Scholar] [PubMed]
- Zeng Z, Hu M, Wang X, Zheng B, Zeng C, et al. (2021) A disinfectant combination for preventing coronavirus 12:22-25.
- Liang H, Zhao L, Gong X, Hu M, Wang H (2021) Virtual screening FDA approved drugs against multiple targets of SARS-CoV-2. JCTS 14:1123-1132.
[Crossref] [Google Scholar] [PubMed]
- Li L, Zhang L, Yang CC (2016) Multi-target strategy and experimental studies of traditional chinese medicine for alzheimer's disease therapy. Curr Top Med Chem 16:537-48.
[Crossref] [Google Scholar] [PubMed]
- Ren P, Fan N, Tian M, Qin Y (2018) Research progress on medical effects of essential oils. J Tradit Chin Med 33:2507-2511.
- Birmpa A, Constantinou P, Dedes C, Bellou M, Sazakli E (2018) Antibacterial and antiviral effect of essential oils combined with non-thermal disinfection technologies for ready-to-eat romaine lettuce. J Nutr Food Technol 1:24-32.
- Reichling J, Schnitzler P, Suschke U, Saller R (2009) Essential oils of aromatic plants with antibacterial, antifungal, antiviral, and cytotoxic properties an overview. Complement Med Res 16:79-90.
[Crossref] [Google Scholar] [PubMed]
- Reichling J, Schnitzler P, Suschke U, Saller R (2011) Antiviral effects of plant-derived essential oils and pure oil components. Lipids and Essential Oils 16:79-90.
[Crossref] [Google Scholar] [PubMed]
- Li H, Jia X (2015) Research progress on the antiviral mechanism of traditional Chinese medicine. J Tradit Chin Med 6:82-85.
- Yao, H (2022) Virtual screening of natural chemical databases to search for potential ACE2 inhibitors. Molecules 27:1740.
[Crossref] [Google Scholar] [PubMed]
- Kiefer MC, Tucker JE, Joh R, Landsberg KE, Saltman D, et al. (1991) Identification of a second human subtilisin-like protease gene in the fes/fps region of chromosome 15. DNA cell biol 10:757-769.
[Crossref] [Google Scholar] [PubMed]
- Vardhan S, Sahoo SK (2022) Virtual screening by targeting proteolytic sites of furin and TMPRSS2 to propose potential compounds obstructing the entry of SARS-CoV-2 virus into human host cells. J Tradit Complement Med 12:6-15.
[Crossref] [Google Scholar] [PubMed]
- Zhao MM, Yang WL, Yang FY, Zhang L, Huang WJ, et al. (2021) Cathepsin L plays a key role in SARS-CoV-2 infection in humans and humanized mice and is a promising target for new drug development. Signal Transduct Target Ther 6:1-12.
[Crossref] [Google Scholar] [PubMed]
- Morse JS, Lalonde T, Xu S, Liu WR (2020) Learning from the past: Possible urgent prevention and treatment options for severe acute respiratory infections caused by 2019‐nCoV. Chembiochem 21:730-738.
[Crossref] [Google Scholar] [PubMed]
- Costanzi E, Kuzikov M, Esposito F, Albani S, Demitri N, et al. (2021) Structural and biochemical analysis of the dual inhibition of MG-132 against SARS-CoV-2 main protease (Mpro/3CLpro) and human cathepsin-L. Int J Mol Sci 22:11779.
[Crossref] [Google Scholar] [PubMed]
- Santos R, Ursu O, Gaulton A, Bento AP, Donadi RS, et al. (2017) A comprehensive map of molecular drug targets. Nat Rev Drug Discov 16:19-34.
[Crossref] [Google Scholar] [PubMed]
- Wu S, Cao J, Wang T, Zhou M (2015) Experimental study on the antifungal and antiviral effects of volatile oil from artemisia argyi leaves on herpes zoster virus. J Chi med 34:70-71.
- Han Y, Dai C, Tang L (2005) Preliminary study on the antiviral effect of volatile oil from Artemisia argyi leaves. Amino Acids &Biotic Resources 2:14-16.
- Zhao Z, Wang L, Zheng L, Geng N, Zhao X, et al. (2015) The inhibitory effect of volatile oil from Artemisia argyi leaves on HBV. Journal of Zhengzhou University 50:301-304.
- Ke M (1982) Physicochemical and pharmacological properties of effective ingredients in Chinese herbal medicine. Hunan Science and Technology Press.
- Hai C, Bai X, Chen H, Yang X, Yang J, et al. (2021) Study on characteristic volatile components of chinese white chrysanthemum by gc-ms combined with chemometrics. Chemical Reagents 43:584-589.
- Ren A, Wang Z, Lu Z, Wang L, Wu Y (1999) Experimental study on the antibacterial and antiviral effects of wild chrysanthemum. Pharmaceutical Biotechnology 4:241-244.
- Zhao H, Zhao Y (2010) Study on effect of ethanol extracts from rollius chinensis bge. on resisting influenza virus in Vitro. China Pharmaceuticals 1:10-11.
- Guo X, Zhang L (2017) Comparative study on volatile oil components in chrysanthemum morifolium from different producing areas. Modern Chinese Medicine 19:821-827.
- Zhang X, Chen X, Wu Y (2021) Research progress on chemical constituents and pharmacological activities of volatile oil of aiye (artemisia argyi). Tradit Chin Med 39:111-118.
- Li JianJun LJ, Ren MeiLing RM, Shang XingChen SX, Lian XiaoYa LX, Wang HongLei WH (2017) Extraction of volatile oil from honeysuckle by distillation and its component analysis. J Henan Agri Sci 46:144-148.
- Wang JianLing WJ, Ni KePing NK, Ji XiaoMing JX, Li BingJie LB, LüQuanJian L (2012) Analysis of the essentlal oil from trollius chinensis bunge bygc-ms and its application in unblended cigarette flavoring. J Henan Agri Sci 41:121-124.
- He S, Zhang C, Zhou P, Zhang X, Ye T, et al. (2019) Herb-induced liver injury: Phylogenetic relationship, structure-toxicity relationship, and herb-ingredient network analysis. Int J Mol Sci 20:3633.
[Crossref] [Google Scholar] [PubMed]
- Guo Y, Bao C, Ma D, Cao Y, Li Y, et al. (2019). Network-based combinatorial CRISPR-Cas9 screens identify synergistic modules in human cells. ACS synthetic biology 8:482-490.
[Crossref] [Google Scholar] [PubMed]
Citation: Zhang H, Guo W, Shen J, Zhang B, Song X (2024) An Anti-SARS-CoV-2 Formula Consisting Volatile Oil from Traditional Chinese Medicine (TCM) Through Inhibiting Multiple Targets In Vitro. J Infect Dis Ther 12:600. DOI: 10.4172/2332-0877.1000600
Copyright: © 2024 Zhang H, et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Share This Article
Recommended Journals
Open Access Journals
Article Tools
Article Usage
- Total views: 355
- [From(publication date): 0-2024 - Nov 23, 2024]
- Breakdown by view type
- HTML page views: 322
- PDF downloads: 33